Defines a CharSequence to which characters can be appended
Interface defining methods common to the TinyTree and the Domino tree model.
This class enumerates the ancestor:: or ancestor-or-self:: axes, starting at a given node.
This is an implementation of the CharSequence interface: it implements a CharSequence as a view of an array.
This class provides a compressed representation of a sequence of whitespace characters.
This is an implementation of the CharSequence interface: it implements a CharSequence as a list of arrays of characters (the individual arrays are known as segments).
Statistics on the size of TinyTree instances, kept so that the system can learn how much space to allocate to new trees
A node in the XML parse tree representing an attribute.
An implementation of the AttributeMap interface based directly on the TinyTree data structure.
The TinyBuilder class is responsible for taking a stream of SAX events and constructing a Document tree, using the "TinyTree" implementation.
Variant of the TinyBuilder to create a tiny tree in which multiple text nodes or attribute nodes sharing the same string value economize on space by only holding the value once.
Monitor construction of a TinyTree.
A node in the XML parse tree representing the Document itself (or equivalently, the root node of the Document).
A node in the XML parse tree representing an XML element.
A node in a TinyTree representing an XML element, character content, or attribute.
TinyParentNodeImpl is an implementation of a non-leaf node (specifically, an Element node or a Document node)
A node in the XML parse tree representing character content
An element node in the TinyTree that has no attributes or namespace declarations and that has a single text node child.
A data structure to hold the contents of a tree.
A node in the XML parse tree representing a text node with compressed whitespace content
This package is an implementation of the Saxon internal tree structure, designed to minimize memory usage, and the costs of allocating and garbage-collecting Java objects.
The data structure consists of a set of arrays, held in the
TinyTree represents one or more root document or element nodes, together with their
subtrees. If there is more than one root node, these will often be members of a sequence, but
this is not essential and is never assumed.
The arrays are in three groups.
The principal group of arrays contain one entry for each node other than namespace and attribute nodes. These arrays are in document order. The following information is maintained for each node: the depth in the tree, the name code, the index of the next sibling, and two fields labelled "alpha" and "beta". The meaning of "alpha" and "beat" depends on the node type. For text nodes, comment nodes, and processing instructions these fields index into a StringBuffer holding the text. For element nodes, "alpha" is an index into the attributes table, and "beta" is an offset into the namespaces table. Either of these may be set to -1 if there are no attributes/namespaces.
A name code is an integer value that indexes into the NamePool object: it can be used to determine the prefix, local name, or namespace URI of an element or attribute name.
The attribute group holds the following information for each attribute node: parent element, prefix, name code, attribute type, and attribute value. Attributes for the same element are adjacent.
The namespace group holds one entry per namespace declaration (not one per namespace node). The following information is held: a pointer to the element on which the namespace was declared, and a namespace code. A namespace code is an integer, which the NamePool can resolve into a prefix and a namespace URI: the top 16 bits identify the prefix, the bottom 16 bits the URI.
The data structure contains no Java object references: the links between elements and attributes/namespaces are all held as integer offsets. This reduces size, and also makes the whole structure relocatable (though this capability is not currently exploited). All navigation is done by serial traversal of the arrays, using the node depth as a guide. An array of pointers to the preceding sibling is created on demand, the first time that backwards navigation is attempted. There are no parent pointers; Saxon attempts to remember the parent while navigating down the tree, and where this is not possible it locates the parent by searching through the following siblings; the last sibling points back to the parent. The absence of the other pointers is a trade-off between tree-building time and transformation time: I found that in most cases, more time was spent creating these pointers than actually using them. Occasionally, however, in trees with a very large fan-out, locating ancestors can be slow.
When the tree is navigated, transient ("flyweight") nodes are created as Java objects. These disappear as soon as they are no longer needed. Note that to compare two nodes for identity, you can use either the isSameNode() method, or compare the results of generateId(). Comparing the Java objects using "==" is incorrect.
The tree structure implements the DOM interface as well as the Saxon NodeInfo interface. There are limitations in the DOM support, however: especially (a) the tree is immutable, so all updating methods throw an exception; (b) namespace declarations are not exposed as attributes, and (c) only the core DOM classes are provided.
The primary way of navigating the tree is through the XPath axes, accessible through the
iterateAxis() method. The familiar DOM methods such as getNextSibling() and getFirstChild()
are not provided as an intrinsic part of the
NodeInfo interface: all navigation
is done by iterating the axes, and each tree model provides its own implementations of the axes.
However, there are helper methods in the shared
Navigator class which many
of these implementations choose to use.
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